Precise Control of Magnetic Nano Particle Formed Microrobot Cluster

2021 WRC Symposium on Advanced Robotics and Automation (WRC SARA) Pub Date : 2021-09-11 DOI:10.1109/WRCSARA53879.2021.9612685

Luyao Wang, Li Song, Lina Jia, Hongyan Sun, Yiming Ji, Yuguo Dai, Lin Feng

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引用次数: 3

Abstract

Many incredible clusters of emergent behaviors exist in natural organisms, and these colonies of organisms exhibit a vigorous ability to adapt to complex and variable environments. Nowadays several artificial microrobot swarms have been developed, but the majority of them usually have only one single rigid structure which lacks adaptability to complex environments. Inspired by the clustering behavior of wild herring, this paper develops a strategy to trigger loose magnetic nanoparticles to form vortex-shaped “flexible” clusters. By programming the magnetic field parameters, the vortex-like swarm of microscopic robots can exhibit both liquid and solid-like behavior, such that the swarm is variable and reconfigurable, capable of easily overcoming complex surface environments composed of biological cells and controlling movement in any direction of the surface. In addition, it can actively approach its “prey” and capture it for transport to a designated location. In the future, deformable vortex-shaped micro-robots will play a valuable role in targeted drug delivery and targeted lesion removal in living organisms.

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磁性纳米粒子形成微型机器人簇的精确控制

自然生物中存在着许多令人难以置信的突发行为集群，这些生物群落表现出适应复杂多变环境的强大能力。目前已经开发了几种人工微机器人群，但大多数人工微机器人群通常只有一个单一的刚性结构，缺乏对复杂环境的适应能力。受野生鲱鱼群集行为的启发，本文开发了一种触发松散磁性纳米颗粒形成涡状“柔性”群集的策略。通过对磁场参数进行编程，旋涡状的微型机器人群可以同时表现出液体和固体的行为，这样的群体是可变的和可重构的，能够很容易地克服由生物细胞组成的复杂表面环境，并控制在表面任何方向的运动。此外，它可以主动接近它的“猎物”，并将其捕获并运送到指定地点。在未来，可变形的涡流型微型机器人将在生物体内的靶向药物递送和靶向病变去除中发挥重要作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 WRC Symposium on Advanced Robotics and Automation (WRC SARA)

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